Torque converting and transmitting mechanism



All@ 8 1.939- f R. LAPsLEY e 2,168,350

TORQUE CONVIR'JING AND 'I RANSHITTING IEGHANISI Original Filed July l2, 1935 5 Sheets-#Sheet 2 Aug. 8; 1939. R, LAPSLEY 2,168,350

" ToRQuE coNvERTlNG AND TRANSMITTING lmcmmrsl Original vFiled July l2, 1933 5 Sheets-Sheet 3 Ag. 8, 1939. RQ LAPsLEY 2,168,350 Y.

TORQU CONVERTING AND TRANSHITTING IECHANISI Original Filed July 12, 1933 5' Sheets-Sheet 4l Vy A Ms Aug. 8, 1939. R. LAPsLEY A2,168,350

TORQUE' CONVERTING AND- TRANSMITTING MECHANIS! Original Filed July 12, 1933 l5 Sheets-Sheet Patented Aug.A 8,1939` I l2,168,350V

TORQUE CQNVERTING AND TBANSMITTIN MECHANISM Robert Lapsley, Berrien Springs, Mich., assignor Vto Clark Equipment Company, Mich., a corporation of Michigan Buchanan,

'Application July 12, 1933, Serial No. 680,115 Renewed July 6, 1936 25 Claims.

The present invention relates generally /to transmissions for automotive vehicles and the like. 'l'he` principal purpose of the present invention is the provision of a new and improved torque converting and transmitting means in which is embodied means arranged to transmit power at such ratio that suillcient vtorque is available for starting and acceleration at the lower speeds, and which also includes automatically controlled means for transmitting power at a direct or one-to-one ratio.

More specifically, one object 'of the present invention is the provision yof transmission apparatus embodying a hydraulic device arranged to transmit power at the lower speeds and including a driving and a driven member with additional means adapted to lock the driving and driven members' together after a given speed has been attained.

another object of the present invention is the -provision of ahydraulic torque converting means arranged to transmit power by means of a uid which serves as a transmitting medium, in connection with a speed controlled mechanical aA mechanical connection between the driving and driven parts when the speed of the driven palrt has attained a predetermin ed or given va ue. l

An additional object of the present invention is the provision of means adapted to automatically delay the actuation vof the governor mechanism until the desired speed has been attained, and a still further object of the present invention is the provision of means to delay the engagement of the clutch parts until the driving and driven members have attained the same speed and rotate in substantialsynchronism.

An additional object of thepresent invention is the provision of new and improved torque converting apparatus which includes a fluid impelling member and a iiuid impelled member and means entirely automatic in operation for transmitting the torque at a multipliedratio at low speeds and which,r after a given speed has been attained, becomes automatically effective in increasing the driving ratio sothat the driving and driven parts parctically rotate together at a oneto-one ratio. In this connection, the present invention further contemplates the provision of governor controlled clutch means in this type of construction in which, when the driving and driven parts are rotating together or substantially so, the governor controlled means becomes clutch actuated by governor mechanism to effect` automatically operable to effect a mechanicalconnection between the driving and driven parts.

Still further, another object of the present invention is the provision of improved synchronizing means, particularly in connection with governor controlled mechanism but not neces- 5 -sarily so, which wembodies means made operative l to connect the driving and driven parts together automatically as soon as the speed of the driven parts begins to exceed thespeed of the driving parts.

Anadditional object of the present invention is the provision of an improved torque converter andtransmitting means which embodies a fluid impeller, a fluid impelled or turbine member, and a stator which is so constructed and arf l5 ranged as to be rotatable in the direction of rotation of the fluid impeller, but prevented from rotating in the other direction by ratchet means serving as a one-way brake. B'yl virtue of this construction, at the lower speeds the stator serves 20 as a stationary guiding member which is sub- Jected tothe residual velocity of the fluid emerging from the fluid impelledmember and can be used, therefore, to redirect the power transmitting nuid into the driving impeller in such `a manner as to retain the kinetic energy of the fluid. Thus,no power is lost and a maximum torque multiplication is secured. At the saine time, by virtue of the stator being rotatable in the one direction as the speed of the fluid impelled member increases. to such a point that the residual velocity of the transmitting uid emerging from the fluid impelled member is less than vthe peripheral speed of said member, the stator can then rotate with the impeller and the fluid impelled member, securing thereby a substan. tially direct drive between Ithe driving impeller l and the driven or uid impelled member. According lto the present invention, therefore, la hydraulic torque converter and transmitting 40 means is provided which automatically secures two driving ratios and these ratios are established automatically and withoutyany attention on the part of theoperator. Further, these ra-y tios are automatically established at the time when such ratios are feasible. l These and other objects and advantages of the present invention will be apparent to those skilled in the art after a consideration of the following detailed description'of the preferred construc- 50 tion, taken in connection with the accompanying drawings, illustrating such construction.

In the drawings: Figure 1 is a vertical longitudinal'section taken through one form of my new and improved V1y connecting the driving and e converter for a in the other direction.

Referring now more particularly to Figure -1 of the accompanying the stationary housing or support for the torque converting and transmitting of the t invention is indicated by the reference `nurnm'al I land-comprises two sections ll'and I2rsnitably connected together by cap screws I3, or the equivalent, insertedthrough openings intheilangeofthe section II andthreadedintothe ding portin of the section I2 which may be provided with or the likeforthatpurpose. The housing section Il'includesaintcrmediateweborwall I5 having suitable remforcing ribs I5 and I1. The intermediate wall I5 terminates radially in wardlyinacentrallydispedbearinghub 2l.

In the present construction, the fluid impeller ordrivingmemberisinilie form ofarotatably meimtedcasingformedintwoparts, and 21-,thecasingpart25 lncludingacentralanged section Il adapted tobesecuredandsupported on the flange of a powei'driven shaft II, such asthecrank ofaninternalcombustionen-J gine. -Forthispurposecapscre'wsl areprovided-end arranged in any manner suitable to the particular installation involved. It will be understood, of course, that' any suitable source of power may be utilised. an internal combustion engine being mentioned as a source Yof power Y, in common use today for automotive vehicles and thelike. -'lheotherdrivingcasingsection21isrigi connected to the section 25 by cap screws l5 or thelike,andpreferably these cap` screwsareutlliaedtomoimtastarterrlnggear 3,6 on the driving member 2l. In uns oase, thore-V -fore, the driving casing 25 and associated parts are utilized as a flywheel for the motor, represented byitscrsnkshaftlli. Asbtshownin Fisure2,inordertoutiliaetherlnggear35,the stationaryhousing Il is provided with a bracket I1di`sposedinsuchapositionastoreceivea starting motor, the pinion of whichis adapted to ibemeshed withthe ringgear Il.

` Thebearinghub 2loftliehouslngsection Ilis'` tor receive suitable bearings for supportingthe driving casing section 21. Por-this purpose,'the rearportion of thedrlving casing secinplace therein by a cover'plate 45`secured to the intermediate screws 46 threaded into threaded bosses 41. The forward portion of the bearing hub 20 carries gasket means 50 of any suitable construction which, in connection with companion gasket means 5l carried by the cover plate 45,serves to prevent the loss of lubricant from the bearing means 42. l

In this connection, as best shown in 'Figure 2, the intermediate wall I5 is formed with a lubricant chamber closed by an extension 5E of the cover plate 45, and a tubular extension 51 including a illler plug 58 provides for supplying lubricant to the chamber 55 by which the bearing 42 isV lubricated.

As mentioned above, the casing 25, supported at its forward portion on the crank shaft 3| ofV the motor and at its rear end by bearing means 42 on the' intermediate wall I5, constitutes the driving member of the transmission. The driven parts'include a driven shaft 50 which is splined for a portion of its length and is provided with a reduced forward end 6I which is piloted in a' suitable bearing opening in the rear end of the crank shaft 3|. Rearwardly of the splined section, the driven shaft 50 is provided with suitable anti-friction bearing 65 by which the rear end of the driven shaft is supported on the rear portion of the driving casing section 21, as best shown in Figure 1, the bearing means 42 supporting this portion of the casing section 21, as described above. The bearing means includes an outer race 6B seated in a suitable groove formed in the'cylindrical portion of the driving casing section 21 and is held therein by a threaded ring member 61. A bellows gland seal 10 has its flange portion rigidly-secured tothe driving casing section 21, as by being interposed between the outer race of .the bearing means 55 and the recess in the casing section 21. The rear portion of the beuowsgiand seal 1o is provided with an anti-friction ring 1I which seats against a second ring member 12 pinned or otherwise secured to the rear end of the driven shaft 60, as indicated in Figure 1y by the reference numeral 14. 'Ihe rear portion of the driven -shait 60 terminates in a flange 16 which is provided with a plurality of threaded openings 11 adapted'to receive suitable ldriving connections, such as a universal joint or the like, by which the drive from the transmission of the present invention is trans- 1 mitted to other vehicle or driven parts.

For transmitting torque from the driving casing 25 to the driven Shaft 60, fluid transmitting means is employed, according to the principles' set forth in the patent to Herman Fttinger, No. 1,199,359, issued September 26, 1916. Such a fluid torque transmission device is known as a fluid c flywheel by virtue of the capacity of the device to not only transmit torque but to act as a ilywheel for the source of power. Generally, such a uid ywheel utilizes the kinetic energy of a moving fluid which is set in motion by a suitably formed impeller. 'I'he uid is delivered to a rotor Aor fluid impelled member which, by virtue of its rotation, absorbs the kinetic energy of the vmoving uid and utilizes the same so that the energy imparted tothe moving uid rotates the driven parts of the device. One of the features of the fluid flywheel just referred to is. that the member which imparts energy to the fluid transmitting means and the member in which the energy 'of the kuid is utilized are-provided with vanes or the like which are so formed that the uid is caused to circulate through passages in the impeller and to be delivered to passages in 'the rotor so that the l5 fluid advances not only around the axis of rotation of the driving and driven members, but is also moved in a spiral path advancing'around a circular axis, the fluid being continually delivered to the rotor or fluid impelled member which derives energy therefrom and returns the uid again to the impeller or fluid impelling member, all as set forth in the patent mentioned above. The uid impelling member or impeller is so designed that the centrifugal force, established by virtue of the rotation of the impeller, delivers the iiuid at high velocity and comparatively 'low pressure into the rotor or uid impelled member. Thus, both the members just mentioned are similar vto turbine wheels of more or less conventional construction. It has been shown that a device of this character is capable of transmitting a -considerable torque more or less independently of the speed of rotation of the driven member. In utilizing these principles, the present invention forms the driving member or driving casing 25 in such a manner that two sets of driving or impeller blades or-vanes are provided, indicated in Figure l by the. reference numerals 80 and 8|, respectively. As shown, these sets of blades or vanes 80 and 8| faceeach other, and the blades or vanes of each set are connected together by a curved wall-which not only reenforces the blades,

but serves to dene a fluid channel referred to later. The curved wall for the set .of blades 80 is indicated by the reference numeral 83 and the curved wall for the set of blades 8| isv indicated by the reference numeral 84.

-The rotor or fluid impelled member is indicated in its entirety in Figure 1 by the reference numeral 90 and comprises a casting or the like having a hub 9|- mounted on the forward splined end of the driven shaft 60 of a nut 92. These splines on which the hub 9| is mountedare of smaller diameter than the remaining splined portion of the driven shaft 60, thereby forming a shoulder 93 against which a collar 94 is disposed, and the collar 94 is engaged by the rear edge of the hub 9| The rear portion of the rotor 90 is supported upon a anged collar |00, the latter being secured to the rotor 90 by cap screws |0| and the collar |00 being seated in non-rotatable relation on the splines of the driven shaft 60.

The driven rotor 00, like the driving member 25, also includes two s ets of blades or vanes |03 and |04 connected together, respectively, by curved walls |05 and |06. From Figure 1 it will be noted that the driving and driven members, 25 and 90, are arranged in such relative positions that the blades or vanes 80 and |03, as well as the blades or vanes 8| and |04, form a closed channel or passage system or circuit in the shape of a gyratory or vortex ring in which a connned uid may circulate Iin a smooth ow.

In transmitting the torque from the driving member 25 to the driven member 90, the ow of the fluid, which is preferably a liquid having small internal friction, is indicated by the arrows in Figure 1. As the driving member 25 rotates, the impeller vanes 80 and 8| cause the coned liquid to rotate therewith. This movement of the liquid is from the axial center of the impeller 25 to the periphery thereof due to the centrifugal force of the whirling liquid. Centrifugal forcecauses the liquid to be ejected from the outer margins of the vanes 80 and 0|, across the relatively small'space betweenY` the member 25and the member 90 to the maar where the kinetic energy of the moving liquid is imposed on the blades or vanes |03 and ditions, the driving and held thereon by means f with two sets of teeth 4apart axially |04 of the driven rotor. Thus, the force exerted on the rotor is dependent on the weight and velocity of the uid. a

After the liquid hasbeen thrown against the blades |08 and |04 of the rotor 90, the liquid flows radially inwardly toward the driven shaft 60 where it is caused to reenter the driving member or impeller 25. Here the liquid again has its velocity increased and is again thrown by centrifugal force against the rotor 00. In this manner, and moving in the closed circuits illustrated, the iluid transmitting medium'continually circulates, flowing radially outwardly of the driving member 25 and radially inwardly of the driven member 90 in alternate relation, receiving energy from the former by having its velocity increased and delivering energy to the latter by having its velocity decreased or its direction-changed, or both, as-will be understood.

In this type of device, substantially the maximum torque can be imposed onthe driven member 90,' even though the latter has not begun to rotate, the difference between the rotation of the driving and driven members being taken up by what is known as the slip in the liquid. As the driven member yields and begins to rotate, the slip becomes less until at the higher speeds the driving and driven members rotate substantially at the same speed. Tests have shown that under these conditions the slip may be as little as 2%. Practically speaking, therefore, under these conand driven rnembers'are hydraulically locked device rotates as a unit and may, therefore, act as a flywheel for the crankshaft 3|, as referred to above.

Itis to be noted that the formation of the driving member 25 as a casing, and by rvirtue of its tight connection seal 10 with the driven shaft 60, a leak tight housing is provided-for the confined uid so that substantially no loss can occur. In the construction illustrated in Figure 1, two separate circuits are shown, but it is to be understood that a greater or lesser number of such circuits may be employed, depending upon the torque desired for predetermined dimensions or vice versa.

As mentioned above, one of the principal purposes of the present invention is the provision of means adapted to mechanically andpositively connect the driving and driven members of the transmission device so that they are vpositively caused to rotate together. To this end, therefore, the present invention provides governor controlled clutch'mechanism which will now be deceives a clutch member |22 having a toothed exterior |23 whereby the clutch member |22 may be slid axially-of the driving casing section 21 into `non-rotatable relation with respect thereto. Of course, any securing means permitting the assembly and attachment of the clutch member |22 in the driving casing section 21 may be utilized. A companion clutch member |25 is splined onto the driven shaft 60 and is provided |21 and |28 and is adapted to be shiftedaxially along the driven shaft 00. The sets of teeth |21 and |28 are spaced of the splined clutch member |25, and disposed between the sets of teeth |21 and |28 is a third set of clutch teeth |30 carried by the clutch member |22. The clutch member |22 with the flange 3| of the enl gine crank shaft and by virtue of the bellows together so that the entire is retained in position inthe chamber |20 2o light tension is disposed means of a spring ring-III or the equivalent.

For shifting the clutch member 25 axially so as to engage the teeth |21 on the clutch member 5 |25 with the teeth m on the clutch member |22, speed responsive means is provided and so actuatedV that the clutch member is not shifted until the driving and driven members 25 and 00 rotate at substantially the same speed or some Preferably, this is ac- The collar or washer 94, which is splined onto the driven shaft 00, is provided with a plurality of hinged weights hinged thereto by pins |4I.

15 Preferably, three weights are provided, but the number of these parts may, ofcourse, vary. A

collar I 42.is also splined onto the driven shaft 60, and this collar is connected, vas by links |40, with the weights |40. A spring of relatively between the collar or washer 04 and the cellar |42 and serves to press the latterfagainstthe flanged collar I 00, as clearly shown'in Fig'ure 1.

A plurality of rods or links are riveted to 25 the collar |42 andare extended axially of the driven shaft through suitable openings in the flange of the collar |00 and into suitable openings in the shiftable clutch member |25. Prefershiftable 30 clutch member 25 bynuts or the equivalent, the

ably, the rods |50 are secured to the central portion of each of the rods |50 being enlarged to provide shoulders maintaining the clutch member |25 and the shiftable colla-r |42 in proper spaced relation.

As will be clear from the-above description. as the rotor sl, together with the driven shaft sn to which it is secured, gainsfspeed, the weighted governor arms |40 will be thrown outwardly under the influence of centrifugal force 'and will act .40 through the links |43 Yto shift the collar |42 and the vshiftable clutchmember |25 connected to it by the rods |50 to the right as 'viewed in Figure 1, thereby tending to engage the teeth |21 on -the clutch niember |25 with the teeth 45 |30 on thefclutch member |22 secured. to the driving casing 25. Preferably, however, this action is delayd until thedriving and driven members, 25 and 00, are rotating at substantially the same speed and at a more or less predetermined .5g rate. .To this end, snap mechanism serving to delay-the clutching engagement has Ibeen provided and will now bedescribed.

'I'he rear'end of the driven shaft 00 carries a plurality of bores |60 in the innermost one of which is disposed a-plunger |6| having a rounded `the tension of. the spring I 53 or conical nose A|02 (see Figure 3) and biased for movement toward the right, as viewed in Figure' 1 by a springiit. Means for adjusting is provided in the 'so form of anadjustable plunger rod |05 which is retained in any position of adjustment by a lock plug |55 or the-equivalent.

Adjacent ,the innermost endl of the inner bore |00 a pair of transverse bores are provided, and

05 in each of these transverse bores there is disposed a plunger or poppet |10 having rounded or conical inner ends cooperating with the rounded or conical end |02 Aon the spring. pressed poppet plunger |0I. The poppets |10 are each provided :70 with a rounded or lconical outer end which is adapted, in the position shown in Figures l and 3. to be disposed ina eroove'or recess |10 (see Figure!) formed in the shiftable clutch member |25. The poppets |10' are of such length that when their outerends are disposed in the recesses section A|20 and |02.

plunger. |0| to yieldingly hold the poppets in the y position shown in Figures 1 and 2. As the speed of the driven shaft 00 reaches a given value, the force of the governor weights |40 becomes sufficient -to overcome the resistance offered by the pOppets |10. When once this resistance is overcome and the poppets |10 are forced inwardly of the driven shaft 00 and out of the notches or 4recesses |10, the poppets no longer oifer any material resistance to the movement of the shiftable clutch member |25, and therefore the entire'force of the rotating governor weights |40 becomes immediately ,effective to. shift the clutch member |25. Figure 4 illustrates the position of thethe nose |52 of the |53 against particularly to Figures 3,

of the splined clutch member or hub |25 just described so as to prevent the engagement of the teeth |21 with the teeth |00 until synchronous speed has been attained. In order, therefore, to further delay the-engagement of the mechanical clutch, the present invention provides a synchronizing gate indicated in its entirety by the reference numeral |00 and consisting of hanged |0| and an interior toothed section |02 adapted to be disposed in the path of movement of the teeth |20 on the shiftable clutch hub |25 to halt the'movement of the clutch hub until synchronous speed has been attained.

The synchronizing gate |00 ismounted on the splines of the driven shaft 00 for rotation with respect thereto, the rotary movement of the synchronizing gate with respect to the driven shaft being limited to an extent approximately equal to one-half the pitch of the lteeth |20 and |02, these two sets of teethhavi'ng the same pitch. In order to thus limit the rotation of the synchroniz-- ing gate |00, the latter is provided with a central portion |05 adapted to seat on the splines of the driven shaft 50 andis provided with slots |05 to which is equal to one-half the pitch of the teeth By virtue of this construction, therefore, the synchronizing gate may b'e moved with respect to the. driven shaft 00 on which the shiftable clutch hub |25 is splined from a position in which the teeth |23 will abut against the teeth |02, as shown in Figure 4, to aposition in' which jthese teeth can be meshed to allow the shiftable clutch hub |25 to complete `its shifting movement, as shown in Figure 5.

.70 Figure 3 represents the position of the before the centrifugal governor weights |40 have I exerted suiiicient force to force the poppet plunger`|0| back against thetenslon of the spring |00. f

is in such a position that the teeth |92 are inthe way of the teeth |29 so that further shifting movement of the shiftable clutch member is prevented, thus `preventing the engagement of the clutch teeth |21 with the clutch teeth |30.

Figure 5 illustrates the position of the parts after the synchronizing gate |90 has been shifted to permit the shiftable clutch hub |25 to move relative to the driven shaft 50 so as tov engage the clutch teeth |21 with the clutch teeth |30, thereby effecting a mechanical and positive driving connection between the driving and driven members 25 and 90. It will be noted that the synchronizing gate so that the latter lie in the ends of the slots |96 opposite to the position in which they lie in Figure 4.

The means for effecting the shifting of the synchronizing gate at the proper moment is entirely automatic, such shifting of the position of the gate being accomplished the moment the speed of the driven rotor beginsto exceed the speed of the driving impeller casing 25. As best shown in Figures 1 and 3, a friction (drive washer 200 is keyed, as at 20|, to the clutch member |22 which, it will be remembered, is in fixed engagement withjthe driving impeller casing 25. By virtue of the keyed connection 20|, the friction drive washer 200 is capable of limited'axial mover |22 to"accomrnodate these springs.

ment with respect to the clutch member |22, thereA being a plurality of springs 203 disposed in suitable bores 204 formed in the clutch member As will be clear from Figures 3, 4 and 5, the springs 203 act to force the friction drive washer 200 toward the flanged portion |9| of the synchronizing gate |90. At all times, therefore, the synchronizing gate |90V is in frictional engagement 4with the driving clutch member |22, and by virtue of this frictional engagement, the synchronizing gate |90 tends to rotate with the driving clutch member l|22. However, the gate |90 cannot rotate with the driving vclutch member |22 except through a limited arc since it is connected to the -therotor 90, the gate is continually urged ahead A'of the4 rotor, the gate |90 being held in theposition shownin Figures 3 and 4 with one end of the slots |96 againstA the rods |50. Thus, the gate teeth |92 are held in line with the teeth |28,

the position shown in Figures 3 and 4, in which they -will prevent the clutch hub |25 from completing its movement, even though the governor weights |40 have exerted suflicient force to ini- 4tially'shift the' clutch hub |25 and to overcome the resistance offered by the spring pressed p oppets |10.

Now in order to provide for the movement of the synchronizing gate out of the way of the teeth. |28 so as to permit the shiftable clutch hub -|25 tov complete its movement fand 'engage the |90 has been shifted relative to the rods |50 other means serving driving clutch member |22, the driving impeller 25 is momentarily retarded. Preferably, this is doneby manipulation of the engine throttle to reduce the speed of the driving impeller. When the driving member 25 begins to slow down, the momentum of the vehicle or other machinery connected with the driven shaft serves to drive l the shaft 50 and the rotor 90 ahead of the driving clutch member |22. Due to the uid slip between the rotor 90 and the driving impellerk 25 and the inertia of the latter and associated parts, the rotor will tend to drive the impeller, but the rotor will start torotate faster than the impeller 25. At the moment this reversal of relative rotation occurs, the synchronizing gate |90 will lag behind with the clutch. member |22 and the impeller, and the shiftable clutch member |25 will advance with respect to the synchronizing gate which is frictionally connected with the clutch member- |22, the rods |50 moving to the opposite end of the slots |96, as shown in Figure 5. Such relative movement will bring the teeth |28 out of line with the synchronizing gate teeth |92 so that now the shiftable clutch hub |25 is free to move and the centrifugal governor mechanism |40 will ,25

complete the engagement of the clutch members |22 and |25, thereby effecting a mechanical direct drive between the driving and driven members 25 and 90. l

Fromthe description so far, as given above, it will be noted that according to the present invention a transmission has been' provided in which the drive is transmitted through a fluid flywheel `arrangement in which a substantially constant amount of torque can be applied to4 the driven parts. However, when the speed of rotation of the driven partshas reached a given value, centrifugal governor mechanism comes into action and attempts to establish a mechanical direct drive between the driving and drivenparts of the transmission. The establishment of this direct mechanical connection is delayed, however, until, not only has the speed of the driven parts reached a given and predetermined value, but

also until the driving and driven partsrotate in substantial synchronism, the establishment of tril e h driven shaft by virtue of the slotted connecsynchronous' speed by momen a y r tardmg t e tion |96 with the rods |50. The frictional enspeed of the? normally driving parts or by any to automatically allow the governor mechanism to complete the positive mechanical direct connection.

Where devices of this type are installed in automobiles and the like to provide so-called automatic transmissions, it is usually desirable that the 'speedlof the automobile shall reach a certain value, say ten or fteen miles per hour, before the mechanical direct connection is to be established. This speed or this value may,

however, vary within wide limits. depending upon the operating .characteristics desired, and of course it will be understood that transmissions of this type may be installed in machines other than automobiles.

It is also usually desirable that'the reverse of the above operation shall not take place until the speed of the automobile shall have been reduced to a low value, Ausually materially lower than the value at which it isdesired to insert the mechanical direct connection in the first place. Thus, in orderthat the automobileA will remain in direct drive orhigh -speed with the motor 'idling or substantially so, it is desirable that themechanical direct drive shall not be disconnected until the speed of the automobile shall V llid ywheel with have been rduced to, say, iive miles per hour, idling speed of the motor.

'I'he present inventionds admirably adapted to secure these relations. For example, from the above description it will be evident that the poppet means |6||18 may be made so stiiI or strong that the direct drive engagement will only occur after the driven shaft rotates at' relatively high speed, corresponding to relatively high speed of the automobile or other machinery for which the transmission of the present inventionis incorporated. As mentionedrabove, the tension of the spring |63 may be adjusted by screwing in or out the plunger |65. As will be apparent, the

restorationV of the hydraulic drive after the me.

chanical direct drive has been engaged is eifected by the shifting of the clutch hub |25 back to the position shown in Figure 1, and this is accomplished by returning the collar |42 to its position against the iianged collar |88. As the speed of rotation of the driven shaft 58 reduces, the cen# trifugal force of the governor weights |48 is likewise reduced and will finally reach a point where the spring |45 is strong enough to shift the clutch hub |25 back to its original position, acting through the shiftable collar |42 and the rods |58. This return spring |45 may. therefore, be made so light that the return of the shiftable clutch hub |25 can occur only when the crank shaft 3| is allowed to idle or at a point` only slightly in excess of the idling speed of the engine. Therefore, after once accelerating the vehicle through its lower speeds and once reaching a speed at which the direct drive can be engaged by momentarily retarding the engine throttle and allowing the governor mechanism |48 to shift the clutch member |25 into engagement with the companion clutch member |22, direct mechanical engagement will be retained until the engine throttle is closed and the vehicle retarded to almost a stop.V

In other words, the relatively light force which the spring |45 can exert determines the point at which the hydraulic drive is reestablished, while the point at which the mechanical direct drive is established is determined `by the tension of the poppet mechanism ISI-|18, each acting more or less independently of the other.` Therefore, after once eifecting the direct drive engagement, the

vehicle may be driven through the direct drive without using the iiuid flywheel, even though the vehicle speedfalls off to the lowest at which the y engine will handle it while in direct drive;

Turning now t`o Figure 6 where I have shown a i governor controlled mechanism for effecting a mechanical direct connection between the driving and driven parts and, in addition, certain-new and useful improvements in the' hydraulic mechanism, the reference numeral .25h-indicates a stationary housingformed in two sections 25| and 252 and serving about the same purpose as the housing I8 described above. The housing section 25| in cludes a central bearing plate 253 secured to the section 25| by cap screws 254 or .the equivalent. In Figure its entirety consists of a casing'section 258 adapted to be secured to the crank shaft 3| of an' engine or other source of 'power in substantially the same way as described above for the form of the invention shown in Figure 1. The other casing section of the driving impeller is indicated by the reference numeral 258 and is secured to the section 258-by cap screws 25| which are also utilized to' connect.` the starter ring gear 252 -withthe impeller 258.

supporting casing or- 6, the' driving impeller is indicated inl by the reference .numeral 258 and means 214 includes an outer raceV 215 which is heldin place by means of a slot and spring ring 216 and by a cover plate 211 secured to the bearing plate 253 by cap screws 288. The inner race 28| A of the bearing means 214 bears against a spacing washer 282 which, in turn, bears against the inner race 283 of a second set of bearings 285, later to be referred to, the inner race 283 seating against a shoulder formed on the driven shaft 21|). A collar 281 is mounted on the rear end of the driven shaft 218 and presses against the flange of a bellows gland seal 288, the collar l281 being held in place by means of a threaded ring gl member 29|. The end of the bellows gland seal 288 opposite the flange is provided with a friction ring 283 which seats against ajcompanionring 284 carried by the cover plate 211. 'I'his construction prevents the escape of fluid from the rear end of the housing 258 where the driven shaft 218 emerges.

The rotor is indicated in its entiretyby the reference numeral 388 and is similar'A to the rotor described above in connection with Figure 1 except that, in Figure 6, the rotor has been made into two relatively movable members. The iirst rotor section 38|. includes blades or vanes 382 adapted to receive the liquid thrown out from the impeller blades 265. The'roto section 38| also includes a hub 385 splined or keyed onto the f driven shaft 218 to rotate therewith thereon by a threaded ring 3|8. The second rotor section is indicated by the reference numeral 3| 5 and under certain conditions of operation serves as-a stationary member or stator and will hereinafter be referred to as the stator. The member 3|5 is keyed or otherwise secured. to the forward'end of a sleeve or tubular member 3|5, being held in place thereon by a threaded ring 3|1.A The tubular member 3|3 is supported on the driven shaft 218 by a plu-l rality of roller bearings328 and by the bearing means 285 referred to above, the latterbearing means including an outer race 32| held in place in the tubular member by a spring ring 323 or the equivalent. 'I'he rear end of the tubular member 3|6 terminates in a-radially outwardly `8.1111 1S held -andh'ence the stator 3|5 as well, from rotating relative to the housing 258 in one direction but providing for its rotation in the other direction.

' disposed ratchet flange- 325 which serves the pur- The ratchet flange 325 and its associated struc- 4 ture is a one-way brake in the nature of an overrunning clutch, and any form of one-way brake or overrunning clutch mechanism may be provided' the 'scope of the present' invention.

Figure17 shows one form of overrlmning clutch structure which includes a plurality of liawlsv 338 pivoted by pins 33 |l to lugs 332 or the equivalent carried by'the central portion ofthe stationary housing section 25|. Each of the pawls 338 is 'provided with anV end 335 adapted to engage one oi' the ratchet teeth on the iiange 325 to prevent to later.

l| by pins 34| carried backward rotation of the tubular member.3|8 on its bearings 285 and 320 carried by the driven shaft 210. As will be clear from Figure 7, however, the tubular member 3|3 is free to rotate in one direction with respect to the housing-section 25|, that direction being indicated by the arrow in Figure '7.

It is desirable to hold the pawls 330 entirely out of engagement with the ratchet 325 when the tubular member 3|6 is overrunning the housing 250 under conditions which will be referred In order to hold the pawls out of engagement with the ratchet 325, a cam ring or control disc 340 is provided and which is mounted on the tubular member 3|6 adjacent to and in frictional engagement withthe ratchet flange 325 but held against more than a -limited amount of rotation with respect to the stationary housing by the pawls 330 and disposed in slots 342 formed in the control disc 340.

The frictional engagement between the control to the pawls 330. The slots disc 340 and the ratchet flange 325 is established by means of a friction ring 345 riveted or otherwise firmly secured to the control disc 340 and.

disposed in a shallow groove 346 formed therein.

Preferably, the friction ring 345 is 'riveted to the control disc 340 as by rivets 341.

The ring or disc 340 is yieldingly .pressed against the ange 325 on the stator sleeve 3|6 by means of a thrust bearing ring including anti-friction balls 35|. (see Figure 7) and connectedwith a radially Vinwardly disposed flange portion 353 on the stationary housing 25| by means of springs 355 or the equivalent disposed in suitable openings formedin the thrust ring and the iange 353. Preferatl means is provided for preventing relative rotation between the thrust ring 350 and the flange 353.

From the above description of the one-way brake construction, it will be clear that the stator sleeve 3|6 is prevented from rotating in a counterclockwise direction as viewed in Figure '7 but is permitted to rotate in a clockwise direction. In doing so, the frictional engagement between the control disc 340 and the flange 325 will cause the disc 340 to move a limited amount relative 340 are formed with inclined portions 360 which cooperate with the pins 34| Vto move the pawls out of 'engagement' with the teeth on -the ratchet 325 and to holdthe pawls in this pos'tion as long as the statoi; sleeve v3I|i rotates in that direction relative to the stationary housing 250. A soon, however, as the stator sleeve`3 I3 tends to rotate in a counterclockwise direction as viewed in Figure '1, the control disc 3 40 will be rotated in the same direction to free 'the pawls 330 to allow them Ato engage in the ratchet teeth on the flange 325. l For this purpose, spring means 365 or the equivalent may be provided for moving the pawls 330' toward the ratchet ange 325.

The stator 3 5 is provided with blades or varies 315 connected together by a curved peripheral wall 316, and the rotor blades or vanes 302 are' similarly connected together by a curved wall 311.

The irnpeller 258 is supported, as in the previous modication, at its front end on the crank shaft 3| of the'motor and at its rear end the irnpeller 258 is supported by bearing means 380 carried by the tubular stator sleeve 3|6. The bearing means 380 includes an outer bearing race 38| held in place in the impeller'258 by means of a threaded ring 383.r A bellows gland seal 385 is provided between this portion. of the impellerl redirectthe fluid '258 and the flanged portion 353 of the stationary housing 250.

The vanes or blades 285, 302 and 315 and the associated walls are so formed and shaped that a maximum turbineaction and-the most efficient return of the power transmitting fluid is secured. More specifically, causes thea power transmitting medium, which is preferably a liquid, to be thrown or discharged from the impeller by virtue of the centrifugal force which, as in the previously described modification, is dependent upon the peripheral speed of the impeller and the weight of the fluid. The kinetic energy thus imparted to the uid is imposed upon the blades or vanes 302 of the rotor 300, and the energy due to the residual velocity of the uid is imposed on the stator blades 315. These blades or vanes by virtue of the ratchet the rotation of the impeller 258' means described above cannot rotate backwardly under this reaction and hence they serve to change the direction of the liquid thus ejected from the rotor blades and to redirect the liquid back into the impeller in the most efficient manner to secure the greatest torque multiplication in the driven shaft 210 possible by a single stage turbine. In thus redirecting the liquid discharged from the rotor. 300 and directing the same into the lmpeller 253, the member 3|5 acts as a true stator or stationary member, being held 'against rotation in a direction to. take the reactions involved by virtue of the pawls 330 described above.

After the rotor 3|5 has attained a speed at which the peripheral velocity thereof 'is as great or greater than the speed at which the power transmitting fluid is ejected out of the rotor and into the stator, the fluid will then tend to drive the stator along with the rotor and impeller. Now, by virtue of the one-way brake mechanism described above which now serves as overrunning clutch means, the member 3|5, which formerly served as .a true stator, is permitted to rotate with the impeller 258 and the rotor 300 in the direction of the arrow in .Figure 7. At this time the impeller and rotor or turbine wheel act as a hydraulic flywheel and the power may be applied to the `ixnpeller 258 until the speed of the rotor 300 reaches approximately the speed of the impeller.

The hydraulic unit thus described is thus capable 'of serving automatically in .two capacities. In the rst place, in getting under way, considerable torque multiplication is possible by virtue of the construction wherein the stator 3|5 serves to back-into the impeller with undiminished velocity, and then as the speed of the rotor 300 increases the construction and arrangement of the stator is' such that it does not which the latter is driven, so that the rotor unit may be hydraulically driven at substantially one -to one ratio with referenceto the impeller unit.

Like theform of the invention shown in Figure 1, Figure v6 illustrates the provision of a mechanical clutch construction adapted to secure a positive mechanical and direct connection between y the driving and driven parts uder the control of governor mechanism and synchronizing mechanism. Generally, the governor mechanism and synchronizing mechanism, as well as the meenam. ical clutch, are of substantially the same construction as described above, there being certain variations to accommodate lthe somewhat .difierent positioning of the rotor relative to the im-v 1 10 the impeller casing 259 insubstantially the Same way that the clutch member |22 is connected with the impeller casing in Figure 1.

'I'he shiftable clutch member 40| carries a plurality of lugs 4|| to which governor arms 4|| are 15 hinged, as by hinge pins 4|2. The governor arms 4|| are weighted, as at M3, and are connected by means of links 4I 5 withsets of anchoring lugs 4| 6 carried by the rotor hub 3|5. The links 4|5 are connected with the lugs 4|| bypivot pins 4|1 or the equivalen A Pppet mechanism is provided for opposing the movement of the shiftable clutch hub 4|| lmtil the rotation of the driven shaft 21| is such that a given force is available for shifting the shiftable s clutch member. The driven shaft 21| is provided with an axial bore 42| in which is disposed a-.

poppet plunger 42| biased for movement in one direction by a poppetspring 422 and held thereby against a pair of poppets 423 disposed in trans- 30- verse bores formed in the driven shaft 21|. The

- poppet spring 422 is capable of adjustment by means of a rod 42| and a pair-of locking plugs 426. The rear end of the bore 42| Vis closed by means of a plug 42|. f

s The poppets 423, like the poppets |1| described above, have their ends rounded or conical,

and the radially outer ends of the poppets 423 are adapted to engage in an interior groove or notch formed in the shiftable clutch member 4||. Thus,the clutch member 40| will not be shifted axiallyalongthe splines on theA driven shaft 21| until 'the centrifugal governor 4|| exerts sumcient force to overcome the poppets. As soon as v this occurs and the clutch member 4|| is shifted' 45 sumciently to force the poppets 423l inwardly, the

poppet mechanism no longeroilers material re. sistance to movement of the clutch member. However, at this time. the form of the invention v shown in Figure `8 provides means for imposinga synchronizing gate to resistiurther movement of-the clutch member until the driving and driven parts of the transmission are rotating in substantial synchronism.

In Figure 6, the synchronizing gate is indicated 5 5 by the reference numeral 43| and rotates with the driven shaft 21| but is capable of limited -rotatim relative thereto. To this end, a friction washer 44| is keyed to the clutch member 4|| to rotate therewith but is allowed to-have axial lmovement .0 with respect thereto and is biased for movement toward the synchronizing gate 43| by a plurality of springs 44. The synchronizing gate |35 is prevented from moving axially under the influence of the spring pressed friction ring 44| by '.05 means of a backingplate l which 1 8 attached to the rotor 3|| and .which is provided withA a plurality of anti-friction balls 'againstwhicli the synchronizing gate 43| is pressed.

The action of the synchronizing. gate |35 is .10 substantially the same as the action of the synchronizing gate.||| described above. As long' as the impeller 25| is rotating faster than the rotor. 3||, the friction drag between the gate 435 and the friction washer 44|1 is suiiicient to hold ,jme synchmmzmg'ea' msnen s position om gate "mwillbemovedoutdthelpthotmnvement aieass'o theteeththereofalinewit'hthesetofteethl on the shiftable clutch member 4|| to prevent the latter from moving axially under the influeneeof theoentrifugal forceofthegovernor arms. As soon, however, as the speed of the impeller 258 5 isredueedso thattherotor lltendstooverrun the impellenthe friction between the synchronizing gate 435 and the friction ring 44| is suiicient to move the synchronizing gate to permit these teeth to move in between the teeth 446 10 to allowthe shiftablechltchmember 4|| to complete. its movement. when this movement is completed 'the direct engagement-between the drivinganddrivenpartsis effected bytheteeth 4|2 meshing with theclutch teeth 4|5. u

The clutchmembu4||iareturnedtotheposi tion showninlsure by a relatively light'spring 45|, and the tension of thisspring and of the poppetmeehaninn42l-42Imaybe arranged independently ofeachotherso as to provide for the m Changement and ement of the mechanical direct connection as desired.

The radiilb outward movement of theweightedgovernor arms 4|| islimited bythe engagement of-the arms with the walls of the impellenandthesameistmeof the formof the invention showninllgure 1. In both cases, the olitermnstendsofthegovernorarmsare formed toengage stop shoukim's or the equivalent, indicated in both l'lgtu'es Land 6 by the reference n numeral 45|. A

The operation of the unit shown in Flsure d overoometbem423'and,seeond,uponthe` commence of between'the rotor andtheimpellersothatthe dthem'dmmlll.-

.mumuraimawmecmnewanenremmemiuv-A torque and conse-l over, according to the principles of the present invention where the stator has the two functions indicated above, after the one stage of torque multiplication has been secured," the device automatically functions as a hydraulic flywheel in which the driving and driven members now constitute the entire fluid circuit, the device then operating to transmit torque at a different ratio. Such two ratios are secured automatically and without any attention on the part of the operator whatsoever and at such times that the change of ratio is feasible under the load and other conditions which exist.

These features are of particular importance where internal combustion engines are employed since it is well known that unless such engines are driven at their rated speed or nearly so, the available torque falls oif rapidly.v The hydraulic units described above therefore form transmission devices which enable the source vof power to develop suiiicient torque or less independently of the speed of rotation of the driven member or impeller. At the 4same time, after the proper speed has been attained, all hydraulic losses and the like are avoided by virtue of the automatically operating mechanicaldirect connecting clutch which connects the driving and driven parts to cause them to rotate together, such connection being automatically effected by the simple operation of momentarily reducing the speed of the engine. So far as I am aware, the prov ision of a fluid flywheel, or of a torque converter, and a centrifugally operated and synchronized mechanical direct drive is'new.

While I have described above the'preferred. construction in which the principles of thepresent invention have been embodied, it is to be understood that vmy invention is not to be limited to the specific means shown and described but that, in fact, widely different means may be employed inthe practice of the broader vaspects of my invention.

What I claim, therefore, and desire to secure I by Letters Patent is:

l. In combination, a torque vconverter comprising fluid-connected driving and driven members, means biased in response to the speed of rotation of the driven member for mechanically connecting both of said members together, and

means for preventing said mechanical connection until the speed of the driven member is substantially equal to the speed of the drivingmember.

2. A transmission comprising driving and driven members, means for clutching said members together to cause them to rotate at a one-toone ratio, centrifugal governor mechanism controlling said means, snap action means offering a substantial force opposing actuation of said governor mechanism'in one direction only and offering substantially no force opposing actuation of said governor mechanism in the other direction, and means biasing said mechanism for actuation in said other direction with a lesser force.

3. A transmission 'comprising driving and driven members,` means for clutching said members together to cause them to rotate at a one-toone ratio, centrifugal governor mechanism controlling said means, means to delay actuation of said mechanism in one Vdirection until a given speed has been attained and including a biased member movable to an inoperative position after the attainment of said given speed, whereby movement of the governor mechanism in said speed before said biased member is restored to operative position.

4. In combination, a torque converter comprising fluid-connected driving and driven members,

, means for mechanically connecting both of said members for rotation together in either direction, said means including relatively movable cooperating clutch parts connected, respectively, with said drivingv and driven members, means acting to prevent the engagement of said cooperating clutch parts, and, means responsive to a..

reduction in speed of said driving member below the speed of said driven member for rendering said preventing means inoperative so as to provide for the engagement of said relatively movable clutch parts.

5. In combination, a torque 'converter comprising uid-connected driving and driven members, means for mechanically connecting both of said members together, said means including cooperating clutch parts connected, respectively, with said driving and driven members, governor mechanism rotatable with said driven member and operative under the influence of centrifugal force for engaging said clutch parts, biased means operative to resist said governor mechanism until a given speed has been attained, and meansloperative upon a temporary reduction in speed of said driving member for permitting said governor mechanism to engage said clutch parts.

6. In combination, a pair of driving and driven members mounted for relative rotation, a pair of clutch parts carried, respectively, by said driving and driven members and adapted to be engaged to cause said members to rotate together, governor mechanism responsive to the speed of rotation of said driven member and adapted to and driven-membersand adapted to be engaged to cause said members to rotate together, means responsive to the speed of rotation of said driven member for urging said clutch parts toward engagement, a gate member interposed between said clutch parts and operative in one position to prevent their engagement, said gate member being ca'rried by said driven member and capable of limited relative rotation, andameans establishing frictional contact between the driving member and said gate member and. operative upon la def celeration of the member relative to the driven member for moving said gate member out of the way of said clutch parts.

8. In combination, a driven member including a shaft and a turbine wheel mounted thereon, a driving member mounted coaxially with respect to said shaft and including a driving casing enclosing said turbine wheel and carrying a uid impeller arranged to discharge iiuid into said turbine wheel in a .plane which is substantially tangential with respect to the circumference of bers, a governor controlled mechanism adapted to' mechanically connect said members for rotation at a one-to-one ratio after the driven member has attained a given speed, and means responsive to the occurrence of relative rotation between said members in a given direction fror controlling the operation of said governor mechanism.

10. In combination, av torque converter ccmprising fluid-connected driving and driven members, va governor controlled mechanism adapted to mechanically connect said members for rotation at a one-to-one ratio after the driven member-has attained a given speed, and means'responsive to relative rotation between said members for positively preventing the governor mechanism from acting until relative rotation in a given direction occurs. 11. In combination, a torqueV converter comprisingfluid-connected driving and driven mem bers, a governor controlled mechanism adapted to mechanically connect said members for rotation at a one-to-one ratio after the driven member has attained a given speed and including an axially shiftable toothed member, and means responsive to the occurrence of relative rotation between said members and including a rotatable toothed member cooperating with said first toothed member for positively preventing the governor mechanism from acting until relative rotation in a given direction occurs.

l2. In combination, a torque converter comprising duid-connected driving and driven members, means for mechanically connecting both of said members together, means responsive' to the speed of rotation of said driven member for establishing a direct mechanical connection between said driving and driven members, a shiftable part blocking the action of said speed responsive means so long'as the speed of the driving member exceeds the speed of the driven member, and

means for moving said shiftable part out of the way of said speed responsive means when the driven member begins to overrun the driving member.

13. In combination, a driven 'member including Ya shaft and a turbine wheel mounted thereon, a

driving member mounted coaxially with respect to a0 said shaft andincluding a driving casing adapted to be connected with a source of power andprovided with a uid impeller arranged to discharge fluid into said turbine wheel in a plane which is substantially tangential with respect to the circumference of said turbine wheel, the latter being arranged to discharge the fluid inwardly toward the impeller, a sleeve journaled on said shaft and extending to a point within said casing, a vaned stator carried adjacent the inner. end of said sleeve and extending from the radially inner portions of said turbine wheel to the radially inner portions of said impellerto direct the fluid from `the turbine wheel into the impeller, a clutch member spline on said driven shaft and engageable with portions of said casing to mechanically connect said driving casing and said driven turbine wheel together, and governor mechanism within said casing for shifting said clutch member.

14. In combination, a housing, a driven mem- 5 ber including a shaft and aturbine wheel mounted thereon, a driving member mounted coaxially with'respect to said shaft and including a driving casing disposed in said housing and embracing the turbine wheel and provided with a 10 fluid impeller arranged to discharge fluid into said turbine wheel, a sleeve journaled on said shaft and extending to a point within said'casing, 'a pair of bearing means for supporting said sleeve on said shaft, one being disposed in a position sub- 15 stantlally betweenY said fluid impeller and said turbine wheel and the other being disposed rearwardly of the driving casing which embraces the turbine wheel, a vaned stator carried adjacent the inner end of said sleeve and said'one bearing 90 means and extending from the radially inner portions of said turbine wheel to the radially inner portions of said impeller to direct the'fluid from the turbine wheel into the impeller, bearing means supporting said shaft adjacent said other bearing 25 means in the rear portion of said housing, and a one-way brake device disposed in a plane adjacent said two last mentioned bearing means in the rear portion of the housing and acting to anchor the sleeve to said portion of the housing to 30 prevent rotation of the stator in one direction.

15. In combination, a housing, a driven member including a shaft and a turbine wheel mounted thereon, a driving member mounted coaxially with respect to said shaft and including a 35 driving casing disposed in said housing and embracing the turbine wheel and provided with a fluid impeller arranged to discharge' fluid into said turbine wheel, a sleeve journaled on said shaft and extending to a point within said casing, o a pair of bearing means for supporting said sleeve on said shaft, one being disposed in a position substantially between said fluid impeller and said turbine wheel and the other being disposed rearwardly of the driving casing which embraces the turbine wheel, a vaned stator carried adjacent the inner end of said sleeve and said one bearing means and extending from the radially inner portions of said turbine Wheel to the radially inner portions of said impeller to direct the fluid from 50 the turbine wheel into the impeller, ,bearing means supporting said shaft adjacent said other bearing means in the rear portion of said housin'g, a one-way brake device disposed in a plane adjacent saidtwo last mentioned bearing means 55 in the rear portion of the housing and acting to anchor the sleeve to said .portion of the housing to p revent rotation of the stator in one direction, and bearing means disposed between the driving casing and the stator sleeve, said last namedwl bearing means being disposed in a plane adjacent said above mentioned one bearing means which is disposed substantially between the fluid impeller and -the turbine wheel.

16. In a hydraulic transmission, a driven part, 65 means for driving the latter including a hydraulic unit and a second vpart rotatable adjacent said driven part, means adapted to drive said driven part independently of said hydraulic unit," and means automatically responsive to the overrunning of said second part by said driven part after said second part has attained a predetermined speed for placing the hydraulic unit out of operation and to provide for the transmission of power 75 to said driven part through said second mentioned means independently of the hydraulic unit.

17. In a hydraulic transmission, a driven part, means for driving the latter including a hydraulic vunit and a second partrotatable adjacent said driven part, means adapted to drive said driven part independently of 'said hydraulic'unit, a ring member carried by one of said parts for relative rotation and frictionally associated with the other part so as to beresponsive to and to be rotated relative to said one part by the overrunning of said second part by said'drlven part for automatically placing the hydraulic unit out of operation` and to provide for the transmission of power to said driven part through said second mentioned means independently of the hydraulic unit and only after the dri-ven part has reached a speed of rotation where it can be handled .by the driving means in a one-to-one drive.

18. In a hydraulic transmission, a driven member, a hydraulic unit for driving the driven member and including a part rotatable about the axis of said driven member and ope'ratively connected to drive said driven member, means providing for rotating saiddrivenmember independently of the operation of said hydraulic unit and including a second member also rotatable coaxially of said driven member, andv means automatically operative when one of said members begins to overrun the other -in one direcl tion after the overrunning member has attained a predetermined minimum speed for' directly.

connecting said two members together to drivesaid driven member independently of said rotatable part. f

19. In a hydraulic transmission, a driven member, a hydraulic unit for driving the driven member and including a part rotatable about the axis of said driven member and operatively connected to drive said driven member, means providing for rotating said driven member independently of uthe operation of said hydraulic unit and including a second member also rotatable coaxially of said driven member, and means deriving power from the rotation of said driven member and operative when one of said members begins to overrun the`other in one direction for directly connecting said two members together to drive said driven member independently of said rotatable part.

20. In a. hydraulic transmission, a hydraulic unitcomprising a driving and a driven part provided with a hydraulic coupling therebetween,

' means adapted to mechanically connect said driving and driven parts so as to rotate together,

and means automatically operative when said'v Vdriven part starts to overrun said driving part above -a predetermined speed of rotation of the driving part for controlling said connecting means.

21. In combination, a housing, a driven meniber including a shaft and a rotor mounted thereon, a driving'member mounted coaxially with Vrespect to said shaft and including a driving oasing disposed in said housing and embracing the rotor and provided with a uid impeller arranged to discharge fluid into said rotor, a vaned reaction member disposed between said fluid impeller and said rotor, a sleeve, a bearing support between said shaft and said sleeve substansaid points of connection serving as a one-way brake device for anchoring the reaction member to said housing to prevent'rotation thereof in one direction.

22. In a variable speed transmission, the couibination, with a driving. shaft, and a driven shaft,

of a hydraulic torque converter having driving and driven turbine wheels which are connected respectively with the driving and driven shafts for producing a multiplication of torquev therebetween, a clutch vfor connecting the driving and driven shafts together in a one-to-one drive, and means for automatically throwing inthe clutch upon a momentary reduction in the speed of rotation of the driving Shat'aIter the latter has acted through the torque converter to bring the driven shaft up to -a speed where it can be handled by the driving shaftin a one-to-one drive.

23. In a variable speed transmission, the com# bination, with a driving shaft, and a driven shaft, of a hydraulic torque converter having driving and driven turbine wheels which .are connected respectively with the driving and driven shafts for producing-a multiplication oftorque therebetween, a clutch for connecting the driving and driven shafts together in a one-to-one drive. means for automatically throwing in the clutch upon a momentary reduction in the speed of rotation of the driving shaft after the latter has acted through the torque converter to bring thedriven sliaftuptoaspeedwhereitcanbehan-- died by the driving shaft in a one-to-one drive, and means for automatically releasingthe clutch when the speed of rotation of both shafts drops below a predetermined minimum.

2 4. In a variable speed transmission, the'combination, with a driving shaft, and a driven shaft, of a hydraulic torque converter having driving and driven turbine wheels which are connected respectively with the driving and driven shafts for producing a drive therebetween, a clutch for connecting the driving and driven shafts'together in a one-to-one drive, and meam for automatically throwing in the clutch upon `a momentary reduction in the speed of rotation ofthe driving shaft after the latter has acted through the torque converter4 tobring the driven shaft uptoaspeed whereitcanbehandledby the driving shaft in'a one-to-one drive.

` 25. In a variable speed transmission, the combination with a driving shaft, and a driven shaft, of a hydraulic torque converter including driving 'and driventurbine wheels and a reaction wheel which are associated respectively with the driving and driven shafts for producing a drive therebetween, a one-way overrunning brake'mechanism on which the reaction wheel is mounted, a clutch for connecting the driving and driven shafts together in a one-to-one drive, means for automatically throwing in the clutchV upon reduction in speed of the driving shaft when the driven shaft has reached a speed where it can be handled by the driving shaft in the one-toone drive.

ROBERT LAPSLEY. 

